N6-Allyladenosine: A New Small Molecule for RNA Labeling Identified

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N6-Allyladenosine: a New Small Molecule for RNA Labeling Identified by Mutation Assay Xiao Shu, Qing Dai, Tong Wu, Ian R. Bothwell, Yanan Yue, Zezhou Zhang, Jie Cao, Qili Fei, Minkui Luo, Chuan He, and Jianzhao Liu J. Am. Chem. Soc., Just Accepted Manuscript • DOI: 10.1021/jacs.7b06837 • Publication Date (Web): 08 Nov 2017 Downloaded from http://pubs.acs.org on November 8, 2017

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N6-Allyladenosine: a New Small Molecule for RNA Labeling Identified by Mutation Assay Xiao Shu,†,# Qing Dai,‡,# Tong Wu,‡,# Ian R. Bothwell,§ Yanan Yue,† Zezhou Zhang,† Jie Cao,† Qili Fei,‡ Minkui Luo,§ Chuan He,*,‡ and Jianzhao Liu*,†,║ †

MOE Key Laboratory of Macromolecular Synthesis and Functionalization, Department of Polymer Science and Engineering, Zhejiang University, Zheda Road 38, Hangzhou 310027, China ‡ Department of Chemistry, Department of Biochemistry and Molecular Biology, Institute for Biophysical Dynamics, Howard Hughes Medical Institute, The University of Chicago, Chicago, IL 60637, United States § Molecular Pharmacology and Chemistry Program, Memorial Sloan-Kettering Cancer Center, New York, NY 10065, United States ║

Life Sciences Institute, Zhejiang University, Yuhangtang Road 866, Hangzhou 310058, China Supporting Information

ABSTRACT: RNA labeling is crucial for the study of RNA structure and metabolism. Herein we report N6-allyladenosine (a6A) as a new small molecule for RNA labeling through both metabolic and enzyme-assisted manners. a6A behaves like A and can be metabolically incorporated into newly synthesized RNAs inside mammalian cells. We also show that human RNA N6-methyladenosine (m6A) methyltransferases METTL3/METTL14 can work with a synthetic cofactor, namely allyl-SAM (S-adenosyl methionine with methyl replaced by allyl) in order to site-specifically install an allyl group to the N6-position of A within specific sequence to generate a6A-labeled RNAs. The iodination of N6-allyl group of a6A under mild buffer conditions spontaneously induces the formation of N1, N6-cyclized adenosine and creates mutations at its opposite site during complementary DNA synthesis of reverse transcription. The existing m6A in RNA is inert to methyltransferase-assisted allyl labeling, which offers a chance to differentiate m6A from A at individual RNA sites. Our work demonstrates a new method for RNA labeling, which could find applications in developing sequencing methods for nascent RNAs and RNA modifications.

RNA, as the courier of genetic information, is a structurally and spatiotemporally dynamic biomacromolecule. RNA labeling offers useful tools for the study of RNA structure1,2 and metabolism,3-7 as well as to identify short-lived RNAs.8 Recent interest in the study of naturally occurring RNA chemical modifications has increased thanks to their previously uncovered biological functions.9-11 Among typical examples are studies of N6-methyladenosine (m6A),12-14 pseudouridine,15-17 and N1-methyladenosine.18,19 We were inspired to discover that artificially designed base analogs with a small modifiable chemical group might be employed by cellular machines as the starting material for RNA synthesis and labeling. As known, 4-thiouridine (4SU), a close analog of uridine, represents an excellent example for RNA labeling,3,4

but compared to uridine, its base pairing property cannot undergo further manipulation and is thus not ideal for absolute differentiation of labeled RNA from unlabeled RNAs by using reverse transcription (RT)-induced mutation assays. Herein we present an adenosine (A) analog N6allyladenosine (a6A) for RNA-labeling applications (Scheme 1). On the one hand, a6A behaves like A and can be metabolically incorporated into newly synthesized RNAs inside mammalian cells. On the other hand, we used the idea of mammalian messenger RNA (mRNA) m6A 20 methyltransferase-assisted chemical labeling to convert specific A within RNA into a6A. After the a6A-containing RNA is subjected to iodination treatment, RT into complementary DNA (cDNA), and polymerase chain reaction (PCR), a6A is read as other bases T/C/G while the unmodified A is still read as A. We designed model reactions of the a6A nucleoside and the a6A-containing RNA oligo in order to prove the labeling-derived mutation assay. This work reveals a new RNA-labeling method and demonstrates its potential for future high-throughput sequencing applications in the RNA field.  Scheme 1. Illustration of RNA Labeling with N6allyladenosine and Its Mutation Assay A Nucleosides: a6A, A, C, G, U

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Journal of the American Chemical Society  First, the metabolic RNA-labeling behavior of a6A was investigated. After incubating a6A nucleoside with HeLa cells for a variable length of time, we extracted the total RNAs, digested them into single nucleosides, and utilized ultra-high performance liquid chromatography coupled with triplequadrupole tandem mass spectrometer (UHPLC-QQQ-MS/MS) in order to quantify a6A level (see Supporting Information (SI)).20,21 The a6A nucleoside was synthesized by a reaction of 6-chloropurine riboside with allylamine as a standard in order to generate the calibration curve (see SI).22 Results show that the a6A/A ratio of total RNA increases from 0.003% to 0.03% in a tested period of time from 5 min to 16 hr (Figure 1A), indicating the incorporation of a6A into RNA through cellular metabolic pathways. Meanwhile, we co-labeled RNAs with a6A and 4SU. 4SU-labled RNAs can be biotinylated and enriched (see SI).23,24 We found that a6A/A values after enrichment were much higher than those of non-enriched total RNAs at the same labeling time points. a6A/A increases to 0.1% for 2 hr and 0.27% for 16 hr. These data suggests that cellular RNAs could indeed be metabolically labeled by a6A.  C Probe1 a A modification yield (%)

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during RT. We speculated if we could synthesize an analog of methyltransferase cofactor S-adenosyl methionine (SAM), which carries the allyl group rather than the methyl, and combines its use with the methyltransferase in order to specifically modify A within the methylation consensus motif to form a6A. Prompted by this idea, we synthesized the allylSAM cofactor that replaces the methyl in normal SAM with the allyl group.25 After purifying m6A methyltransferases METTL3/METTL14 heterodimer (MT) complex and synthesizing random-structured RNA oligos with/without m6A modification and/or consensus motif GGACU (probes 1−3, Figure 1B),20 we went on to test their allyl-transfer activity. Results show that RNA probe 1 with GGACU motif was active, while probe 2 with GGm6ACU and probe 3 with GGAUU were inactive for the allyl transfer (see SI). Next, we quantitatively characterized the modification yield for probe 1 with different equivalents of MT (Figure 1C). Increased load of MT from 1 to 3 equivalents enhanced the allyl modification yield from 0.4% to around 8%. The MT complex exhibits a much lower kcat and a higher Km values from MichaelisMenten kinetics studies in the presence of allyl-SAM than with normal SAM cofactor (see SI), which explains the low reaction yield for allyl-SAM. The allyl substitution may not fit the MT cofactor-binding pocket of the native methyltransferase. Future protein engineering will be performed in order to address this limit of the current system. With the two above labeling strategies confirmed, we next studied the chemical treatment of a6A-modified RNA and explored its resultant effect on the RT process. We thought that the double bond of the allyl group at the N6-position of A (4) could be readily iodized under mild conditions and that the iodinated alkyl chain (5) could spontaneously attack the N1position of A in order to generate N1, N6-cyclized form (6, 7) (Scheme 2). Since the hydrogen bonding sites of A are occupied, mutations at opposite site can be readily induced during RT and also detected in cDNA sequencing.26  Scheme 2. Iodination of N6-Allyladenosine Leads to Formation of N1, N6-Cyclized Adenosine, Which Induces Mutation during Reverse Transcription HN N N

 Next, we explored m6A methyltransferase-assisted a6A labeling in potential applications. m6A is the most prevalent internal modification in mRNAs of higher eukaryotes at 1−3 residues per message, and carries fundamental biological functions.12,13 The mRNA m6A modification is sequence specific with GGACU predominant inside cells.12,13 The modified m6A behaves like A and reversely transcribes to T

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Figure 1. (A) Quantification of total RNA a A/A ratio versus different a6A labeling time in HeLa cell using UHPLC-QQQMS/MS. The a6A-labeled RNAs were enriched and their a6A levels were measured for comparison. (B) Test of the allyl transfer ability of mRNA m6A methyltransferases METTL3/METTL14 heterodimer (MT) in the presence of allyl-SAM cofactor on different RNA probes (1−3) with/without m6A and/or m6A consensus motif. (C) Quantification of the allyl-transfer efficiency on probe 1 with different equivalents of MT using UHPLC-QQQMS/MS. The modification yield was calculated by generated a6A per probe 1.

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RT = Reverse transcription cDNA = Complementary DNA Seq = Sequencing

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 In order to prove the proposed chemical treatment process as shown in Scheme 2, we characterized the consecutive iodination and cyclization steps of model nucleoside a6A by standard NMR and mass spectroscopy (see SI). The

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spectroscopic data indicated that the formation of fivemembered N1, N6-cyclized product was favored. To mimic mRNA, we synthesized a6A-containing RNA oligo27 probe 8 with a GG(a6A)CU motif and converted it into cyclized form 9 using similar protocol to that of the a6A model nucleoside (see SI). The MALDI-TOF mass spectrometry result (Figure 2A) showed that probe 8 was converted to probe 9 with a molar mass increase of ~127, equivalent to an iodine atom mass, which clearly supports our proposed RNA post-treatment reaction mechanism.  A

Probe 8: 5’-pACUCGUCUGGXCUAAGCUGCUCA-3’ X = a6A [MH]+ 7331

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80% 60%

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Figure 2. (A) MALDI-TOF spectra of a6A-modified RNA oligo (Probe 8) and its iodination-induced N1, N6-cyclized form (Probe 9). (B) Percentages of mutation of a6A and its cyclized form into other bases after reverse transcription using HIV enzyme and high-throughput cDNA sequencing.

 Our next step was to investigate the RT reaction of these modified probes. By following NEB small RNA library protocol, we ligated probes 8 and 9 with a 3`-adapter, annealed the 5`-primer, and then ligated to the 5`-adaptor. The HIV enzyme was selected as the reverse transcriptase26 because it could tolerate more structural variations and allowed for more read-through compared to normal enzymes that cause RT stop. After RT, the cDNAs were amplified and subjected to high-throughput sequencing. About 5.0 and 3.8 million reads were collected in order to calculate cDNA mutation rates of a6A and N1, N6-cylized A in probes 8 and 9, respectively. Bioinformatic analysis revealed that a small

portion (~5%) of a6A sites were mutated to T/C/G, while N1, N6-cylized A showed up to ~70% mutations to T/C/G (Figure 2B and see SI). The clear mutation contrast indicates that the combination of a6A labeling and mild post-chemical treatment could represent a strategy for identifications of RNA methylations. We further tested a biological sample in order to validate the MT-assisted a6A-labeling method. Following a typical protocol (see SI), the polyadenylated RNAs from HeLa cells were purified, labeled in the presence of METTL3/METTL14 and allyl-SAM cofactor, iodinated, cyclized, and reverse transcribed to cDNA using the HIV RT enzyme. A known GGACU site from mRNA ACTB was chosen as an example, whose m6A methylation fraction within HeLa cells has been determined to be ~20% (~80% A and ~20% m6A) using the SCARLET (site-specific cleavage and radioactive-labeling followed by ligation-assisted extraction and thin-layer chromatography) method.28 The corresponding cDNAs, derived from labeled and unlabeled RNAs, were sequenced to compare their mutation patterns using standard TA cloning technique (see SI). The result displayed that a mutation frequency of 17% was observed for the selected ACTB GGACU site (see SI), whereas the nearby UGACU site did not reveal mutation, indicative of high sequence specificity. The low allyl transfer activity of the methyltransferase of the current system and the fact that not all N1, N6-cylized A generate mutations contributed to the low mutation frequency. This method did show its promise for differentiating m6A and A on cellular RNAs at potential base-resolution, however. Further efforts will focus on METTL3/METTL14 protein-engineering based on their crystal structure29 in order to better accommodate allyl-SAM cofactor and increase RNA-labeling efficiency. In summary, we found a6A as a new small molecule probe for RNA labeling through both metabolic and MT-assisted pathways. With mono-substitution of allyl group at N6position of A, a6A in labeled RNA behaves like A, and can be chemically treated by iodine under mild buffer conditions in order to form N1, N6-cyclized A, which induces mutations to other bases during RT to cDNA. The model reactions of single a6A nucleoside and a6A-containing RNA oligo fully support our proposed labeling-coupled, post-treatment-induced mutation mechanism. The current a6A-labeling method will find potential applications in the RNA research field, such as nascent RNA sequencing and RNA decay dynamics. Meanwhile, the MTassisted allyl-labeling method suggests a new approach to sitespecifically label RNA with modifiable chemical group, which can be extended for other enzyme-assisted base modifications. We also think that the MT-assisted a6A labeling could be applied toward potentially differentiating m6A from A transcriptome-wide. Based on the principle that MT can install the allyl group on unmodified A within the consensus motif while the existing m6A in the motif is inert to allyl labeling, we may acquire information of m6A stoichiometry at a specific mRNA modification site. We also think the introduction of a6A to generate mutations could be a concept quite useful in developing new sequencing technology to interrogate dynamics of transcriptomes in the future.


ASSOCIATED CONTENT Supporting Information

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The Supporting Information is available free of charge on the ACS Publications website at DOI: xxxxxx. Experimental section, Schemes S1−S3, and Figures S1−S14 (PDF)


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AUTHOR INFORMATION

Corresponding Authors

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*[email protected] *[email protected]

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ORCID Qing Dai: 0000-0002-8578-1568 Mingkui Luo: 0000-0001-7409-7034 Jianzhao Liu: 0000-0001-9465-6075

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Author Contributions #

X. S., Q. D. and T. W. contributed equally to this work.

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Notes The authors declare no competing financial interests.


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ACKNOWLEDGMENTS

We thank the National Key Research and Development Program of China (2017YFA0506800), National Natural Science Foundation of China (21642015), and National Institutes of Health of United States (HG008935 to C.H., R01GM096056 to M.L., and K01HG006699 to Q.D.). J. L. thanks the Thousand Young Talents Plan of China and Hundred Talents Program of Zhejiang University. C. H. is an investigator of the Howard Hughes Medical Institute. We thank S. Frank, MA for editing the manuscript.

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